RESEARCH OF PERMANENT MAGNET GENERATOR WITH COMPENSATED REACTANCE WINDINGS · RESEARCH OF PERMANENT...
Transcript of RESEARCH OF PERMANENT MAGNET GENERATOR WITH COMPENSATED REACTANCE WINDINGS · RESEARCH OF PERMANENT...
RESEARCH OF PERMANENT MAGNET
GENERATOR WITH COMPENSATED
REACTANCE WINDINGS
ABSTRACT
In this article, a patented “bifilar” coil (BC) type permanent magnet generator (PMG) is
constructed for scientific research and comparison with other technologies. The features, working
principle and elements of the BCPMG are analyzed.
The BCPMG is developed from the iron-cored “bifilar” coil topology (1) in an attempt to
overcome the problems with current rotary type generators, which have so far been dominant on the
market. One of the problems is armature reactance , which is usually bigger than resistance .
The circumstance creates difficulties for designers and operators of the generator. That is why
patented technology is offered to partially remove or absolutely neglect the reactance of the
machine. Drawings of the PMG parts and assembly are added. A finite element magnetic model
(FEMM) is presented and analyzed. An experimental analysis of the PMG characteristics, such as
no-load losses and EMF vs. speed, loaded voltage drop, power output and efficiency vs. load
current at different speeds.
INTRODUCTION
Relevance of the topic. Classic generators are based on electrical induction or electric
currents and magnetic fields. Each electric machine that uses permanent magnets, can act as a
generator or motor. One of existent problems of manufactured electric generators is that the coil
reactance , the most common, is greater than the active coil resistance . This fact creates
difficulties for designers and operators of generators. The proposed generator or motor should
partially or completely compensate reactance.
The object: Patented PMG prototype with reactance compensated winding.
The aim: Research the type of patented PMG, which is claimed to have significant internal
circuit reactance compensation by winding special coils and construction of before unseen machine.
Methods. Design aspects are evaluated with the help of literature, scientific articles and patent
analysis of existent PMG technologies. Prototype is designed and drawings are made with
SolidWorks. Magnetic analysis is conducted with FEMM (2D) and EMS add-on for SolidWorks
(3D). Electrical schematics are drawn with EAGLE CAD. Experiments are conducted in Klaipeda
university LAB facilities. Achieved data is analyzed and characteristics plotted with MS Excel.
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1. DESIGN ASPECTS OF PMG
1.1. Fig. 3D isometric view of PMG construction
1.1. Finite element magnetic model
A half of this PMG construction is unfolded into linear type and modeled in 2D
environment. Down below cores are shown as poles with wound coils around them and the magnets
from both sides surface mounted on iron plate. Another half of the generator is eliminated, because
it is impossible to have a full model in 2D environment.
1.2. Fig. Magnetic circuit flux lines of PMG topology with double magnets.
This topology has 4 magnets for 3 stator rods or 2 pole pairs for 3 phases. The original plan
was to put 10 permanents magnets on each of the four parts of the rotor. The reason is due to little
magnetic field interacting, if every second magnet from top and bottom is eliminated, there is only
half area left for the other magnet pole, while the first one covers a full area, which causes high
cogging torques while spinning and only half of the flux from magnets is used. This problem has
been fixed by mounting 20 permanent magnets on each of the four parts of the rotor. With the
configuration, while the one coil faces one pole (north for example), the following two coils face 3
quarters of a south pole and a quarter of a north pole so the magnetic force of the coil A is equal to
the magnetic force of the coils BC.
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1.3. Fig. Magnetic circuit flux lines of PMG topology with fewer magnets.
A magnetic transition between rotor and stator is shown below in steps.
Step 1
Step 2
Step 3
Step 4
Step 5
Step 6
Step 7
Step n
1.4. Fig. Magnetic circuit flux lines of PMG while moving through steps.
A 3D finite element analysis is made to show relationship between magnets and stator rods.
For that task a 1/5 segment of the generator is cut out and shown below.
1 5
1 1 1
3
3
3
2
2
2
5
1.5. Fig. 1/5 segment of patented PMG active material, magnetic flux density vector plot (front
view)
1) Magnets;
2) Windings;
3) Ferromagnetic cores;
4) Magnetic flux lines with direction arrow;
5) Iron or steel non-laminated core;
6) Rotor supporting part (non-magnetic);
7) Shaft.
1.6. Fig. 1/5 segment of patented PMG active material, magnetic flux density vector plot (top view)
1.7. Fig. Magnetic flux density continuous fringe plot on several sections: A – cross section of
magnet array, B – cross section of coils
1.8. Fig. Magnetic flux density continuous fringe plot on several sections: C – axial section of core
phase C, D – axial section of core phase A
Further a 3 phase current is applied to show the relationship between wound stator and magnets.
A
B
D C
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1.9. Fig. 1/5 segment of patented PMG active material magnetic flux density with applied 3 phase
current 10A RMS
1.10. Fig. Magnetic flux density with applied 3 phase current 10A RMS axial section of first wound
rod (right side view)
1.11. Fig. Magnetic flux density with applied 3 phase current 10A RMS cross section of first array
of magnets (front view)
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2. EXPERIMENTAL RESEARCH OF PMG
2.1. Measurement equipment and specifications
2.1. Table. Measurement device
Measurement
device Model AC/DC Max scale
Tolerance
class Use
Ampermeter M1500T3
1984 DC 1,5
DC motor
armature
Voltmeter M1600
1979 DC 1,5
DC motor
armature
Multimeter Agilent
U1241A AC/DC 1000V
PMG voltage and
frequency
Multimeter Mastech
MS8222H AC/DC 10A PMG current
2.2. Table. Parameters of driving machines
Driving machine Model Power Gearbox Speed Year
DC motor П-42 7,2
kW No 2800 rpm 1976
Induction motor
– Lathe
Красный
Пролетарий
1K62
10 kW Yes
(Multiple)
1450 rpm
(50, 63, 80, 100, 125, 160, 200,
250, 315, 400) 500, 630
1971
2.2. Analysis of the results
2.2.1. No-load data analysis
The No Load results of the experiment provide the information of power losses in
mechanical and magnetic (eddy currents) parts, the size of EMF induced.
2.3. Table. Motor current voltage data from A2
0 0,90 0,93 0,98 1,01 1,04 1,08 1,13 1,16 1,19 1,22
0 0,90 0,94 0,99 1,02 1,05 1,09 1,13 1,17 1,20 1,23
0,000 0,130 0,165 0,215 0,245 0,275 0,315 0,360 0,395 0,425 0,455
1,26 1,31 1,35 1,39 1,42 1,44 1,48 1,53 1,57 1,60 1,64 1,68
1,27 1,32 1,35 1,39 1,42 1,45 1,49 1,53 1,58 1,61 1,65 1,69
0,495 0,545 0,580 0,620 0,650 0,675 0,715 0,760 0,805 0,835 0,875 0,915
Where – Mean armature current of the motor;
min, max – Electronic unstable measurement range.
2.1. Equation. Arithmetic mean (2)
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Applied arithmetic mean value for the armature current:
2.4. Table. Motor terminal voltage data
0,0 6,0 7,8 10,2 11,4 12,4 13,9 15,8 17,2 18,4
0,0 6,1 7,9 10,3 11,5 12,5 14,0 15,9 17,3 18,5
0,00 6,05 7,85 10,25 11,45 12,45 13,95 15,85 17,25 18,45
0,00 0,07 0,09 0,12 0,14 0,16 0,18 0,21 0,23 0,24
21,1 22,6 23,7 24,7 25,7 25,6 26,8 28,1 29,1 30,1 31,1
21,1 22,7 23,8 24,8 25,8 25,7 26,9 28,2 29,1 30,2 31,2
21,10 22,65 23,75 24,75 25,75 25,65 26,85 28,15 29,10 30,15 31,15
0,28 0,31 0,33 0,36 0,37 0,39 0,41 0,44 0,46 0,48 0,50
Where – Mean terminal voltage of the motor;
– Armature resistance.
Applied arithmetic mean value for the armature voltage:
2.2. Equation. Ohm's law (3) (4 p. 54) (5)
Where – Resistance in ohms;
– Electric potential difference in volts;
– Electric current in amperes.
Applied Ohm’s law for the armature internal resistance voltage drop:
2.5. Table. PMG terminal EMF frequency data
0,00 7,52 11,45 15,10 17,18 19,32 22,17 25,58 28,18 29,97 31,99
0,00 7,77 11,52 15,15 17,22 19,27 22,23 25,65 28,22 30,04 32,03
0,000 7,645 11,485 15,125 17,200 19,295 22,200 25,615 28,200 30,005 32,010
33,76 36,15 38,47 40,40 39,48 41,11 42,94 44,53 46,73 33,76 36,15 38,47
33,92 36,24 38,50 40,45 39,42 41,14 42,95 44,77 46,75 33,92 36,24 38,50 33,840 36,195 38,485 40,425 39,450 41,125 42,945 44,650 46,74 33,840 36,195 38,485
Applied arithmetic mean value for the frequency:
In order to calculate the real mechanical and magnetic losses, we need to subtract Copper losses
from power fed to the motor.
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2.3. Equation. Electrical power (6) (5)
Where – Electric charge in coulombs;
– Time in seconds;
Applied electric power equation for fed power:
2.4. Equation. Joule’s first law (heating) (7)
Applied Joule’s first law for copper losses in motor armature:
The mechanical and magnetic losses achieved from:
Copper losses are insignificant compared to mechanical and magnetic losses.
2.6. Table. Power losses, calculated data
0,00 0,79 1,30 2,20 2,81 3,42 4,39 5,71 6,81 7,84 9,01
0,00 0,01 0,02 0,03 0,03 0,04 0,06 0,07 0,09 0,10 0,12
0,00 0,78 1,28 2,18 2,77 3,38 4,34 5,63 6,72 7,74 8,89
10,44 12,34 13,78 15,35 16,74 17,31 19,20 21,39 23,43 25,18 27,26 29,42
0,14 0,17 0,19 0,22 0,24 0,26 0,29 0,33 0,37 0,40 0,44 0,48
10,30 12,17 13,58 15,12 16,50 17,05 18,90 21,06 23,05 24,78 26,82 28,94
Notice: other shown values are calculated the same way as in the example before.
The curve in figure 2.1 is plotted to show the relationship of power loss and speed, the trend line
equation describes it:
2.1. Fig. Mechanical and magnetic power losses versus frequency as TG signal
The no-load data plot of EMF vs. speed curves is shown in figure 2.2. All the mean
value calculations are done using equation 3.1 in MS Excel.
ΔP(f) = 0,0001f3 + 0,0046f2 + 0,0262f + 0,1773
0
10
20
30
40
0 10 20 30 40 50 60
Po
we
r lo
sse
s , W
Frequency, Hz
Measured
Predicted
10
3 plotted curves are shown as a linear relationships and very low difference in figure 2.2. A
trend line is added and equation describing the curve is generated.
2.2. Fig. EMF vs. frequency as AC TG speed signal (OCC)
2.2.2. Load data analysis
The same mean value equation is applied for voltage and current data. The plot is
constructed from raw data to show relationship of output characteristics at different
speeds. Armature active resistance is per phase.
Due to lack of accuracy in measurements, such as inductance in variable resistors, calculated
characteristics are added for comparison. The calculated parameters are presented in table below.
2.7. Table. The parameters of calculated curves
8,75 11,02 14,14 17,80 22,89 28,80 44,08 56,49 71,11
56,51 70,86 90,59 113,74 145,93 183,31 279,19 357,29 448,90
2,095 2,195 2,250 2,260 2,300 2,315 2,340 2,370 2,365
25,53 31,09 39,31 49,57 62,85 78,70 118,99 150,51 189,61
134,2 183,7 251,4 328,6 442,5 573,5 916,0 1204,6 1529,5
Where – Short circuit current in amperes;
– Synchronous reactance in ohms.
– Useful output power in watts;
Applied formula generated from trend line for EMF calculation:
2.5. Equation. Synchronous impedance using Ohm’s law for AC circuits
2.6. Equation. Reactance calculation from scalar vector formula
Relation between synchronous reactance and frequency is plotted in figure 2.3. A
linear trend line is added and equation describing the curve generated. That is stated to show, that
there is no non-linearity in PMG stator circuit.
E(f) = 6,3244f + 1,1674
0
100
200
300
400
0 10 20 30 40 50 60
EMF,
V
Frequency, Hz
EMF vs Frequency A
EMF vs Frequency B
EMF vs Frequency c
Predicted
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2.3. Fig. Linear relationship of reactance vs. frequency
Predicting short circuit current using correlated values of and .
2.7. Equation. Short circuit current of SG with armature resistance (8 p. 330)
Substitute curve equations of EMF and reactance and get
Which describes the curve in figure 2.4.
2.4. Fig. Short circuit current vs. speed relationship
2.8. Equation. Vector and scalar representation of terminal voltage based on Kirchhoff’s II law
2.9. Equation. Relation between terminal voltage and load current
Described by equation 6.36 from (8 p. 330) if
Substitute of above equations to terminal voltage .
2.10. Equation. Terminal voltage of PMG performance
Which is used in MS Excel to get results plotted in figure 2.5.
Xs (f) = 2,6141f + 3,6992 0
50
100
150
200
0 10 20 30 40 50 60 70 80
Re
acta
nce
, Ω
Frequency, Hz
Calculated
Predicted
0,0
0,5
1,0
1,5
2,0
2,5
0 20 40 60 80
Cu
rre
nt,
A
Frequency, Hz
Predicted
Measured
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2.5. Fig. Terminal voltage vs. load current performance characteristics at different speeds (measured
and calculated)
An interpolated surface plot is generated to have a better view.
2.6. Fig. Terminal voltage vs. load at different speeds (surface plot)
The curve of independent PMG displays armature voltage fall by quarter ellipse trajectory
because of synchronous reactance of the system. Measured curves seem to be lower, because the
load resistors have (8 p. 331), at small load and short circuit,
at .
The power output curves are calculated from performance
characteristics.
2.11. Equation. 3 phase electric power of SG
Assuming that , therefore the function describing the curves is:
This equation is used in MS Excel to get results plotted below:
0
50
100
150
200
250
300
350
400
450
500
0,0 0,5 1,0 1,5 2,0 2,5
Arm
atu
re V
olt
age
, V
Current, A
0,0 0,5 1,0 1,5 2,0 2,5
Current, A
70,80 Hz
56,50 Hz
44,08 Hz
28,80 Hz
22,89 Hz
17,80 Hz
14,14 Hz
11,08 Hz
8,75 Hz
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2.7. Fig. Power output vs. load current performance characteristics at different speeds (measured
and calculated)
Notice that measured curves are slightly lower than the calculated one, which is due to the
load device . Evaluated measured , while calculated is
(the difference in frequency is insignificant). Maximum
power output points are shown in figure 2.7 for the best performance at different speeds
An interpolated surface plot is generated to have a better view.
2.8. Fig. Output power vs. load at different speeds (surface plot)
In order to calculate energy conversion efficiency curves, we have to use efficiency formula
(9 pp. 52-54):
where – applied input power to the shaft in watts.
This equation is used in MS Excel to get results plotted in figure 2.9.
0
200
400
600
800
1000
1200
1400
1600
0,0 0,5 1,0 1,5 2,0 2,5
Po
we
r, W
Current, A
0,0 0,5 1,0 1,5 2,0 2,5
Current, A
max P
70,80 Hz
56,50 Hz
44,08 Hz
28,80 Hz
22,89 Hz
17,80 Hz
14,14 Hz
11,08 Hz
8,75 Hz
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2.9. Fig. Efficiency vs. load current performance characteristics at different speeds (measured and
calculated)
All power losses consist of mechanical, magnetic and electric (9 p. 211):
Mechanical losses due to friction in bearings, ventilation.
Magnetic losses due to core hysteresis, eddy currents.
Electric losses due to electric resistance of the copper.
An interpolated surface plot is generated to have a better view.
2.10. Fig. Efficiency vs. load current at different speeds (surface plot)
Efficiency vs. power output performance , where dots are .
0
20
40
60
80
100
0,0 0,5 1,0 1,5 2,0 2,5
Effi
cie
ncy
, %
Current, A
0,0 0,5 1,0 1,5 2,0 2,5
Current, A
70,80 Hz
56,50 Hz
44,08 Hz
28,80 Hz
22,89 Hz
17,80 Hz
14,14 Hz
11,08 Hz
8,75 Hz
15
2.11. Fig. Efficiency vs. load current performance characteristics at different speeds
(before and after overload)
3. GRATITUDE
MITA (Agency of Science, Innovation and Technology) for VP2-1.3-ŪM-05-K “Inočekiai
LT” (Innovation checks) “2007-2013 growing economics program” for supporting project
“Research of innovative bifilar type electric generator or motor”.
EMWorks (ElectroMagneticWorks Inc.) for trial license of software EMS, a SolidWorks
add-on for electromagnetic analysis and simulation studies.
4. CONCLUSIONS
4.1. Parameters of the PMG and comparison
In table below parameters of patented and 2 more of reviewed generator types are shown.
4.1. Table. Practical parameters of the PMG topology
Parameter Symbol Value
Load current 1,65
Output power 1500
Rated speed 840
No-Load EMF 446
Voltage at rated power 309
Efficiency 92,4
Rated Power factor 0,69
Total mass 55
Output power per active mass 38,4
Output power per volume 138
Number of rotors 2
Number of poles (pair poles) 20 (10)
Number of coils 30
Number of loops per coil 375
Active diameter 150
Rotor inertia 29,58
Phase armature resistance 8,7
Phase synchronous reactance 186,7
16
Phase inductance 442,5
Output frequency 70
Cooling Natural
4.2. Material consumptions
4.2. Table. Consumed material quantity
Material Mass, kg Number of pcs. or pkg.
Copper 13 30 coils
Laminated steel 20,7 15 rods 20x25x352
Non-laminated steel 4,4 4 rings, 1 shaft, fasteners
NdFeB N45 magnets 3,3 80
Wood Epoxy Fiber 10,3 5 parts
Polyethylene 1,8 2 cylindroids
Bearings 0,2 3
4.3. Experiment characteristics
Power no-load losses vs. speed characteristic is a square function of speed (frequency),
which include friction, ventilation and iron losses (induction, eddy currents), at it
reaches of power loss.
No-load EMF vs. speed (frequency) characteristic has linear relationship.
As PMG is loaded, terminal voltage fall by quarter ellipse trajectory due to synchronous
reactance . Measured curves seem to be lower due to the load resistors with
at small load and short circuit, at .
Power Output vs. load current measured curves are slightly lower than the calculated one,
which are due to the load device . Measured ,
while calculated is . For applications a max power
output points are shown in figure 2.7 for the best performance at different
speeds .
Efficiency covers a large area at different speeds and load currents, at efficiency
almost same . The bigger the speed, the bigger the load currents available
for higher efficiency, nominal thermal current is the limit, practically ,
, which is preferred to be rated, because magnet’s Curie temperature . The
machine can be driven to produce .
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